Determining motion of a moveable platform

ABSTRACT

In some examples, to perform motion detection of a moveable platform, variance values based on acceleration data from an accelerometer on the moveable platform are computed. Using the computed variance values, it is determined whether the moveable platform is in motion.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims the benefit under 35 U.S.C. § 119(e) of U.S. Provisional Patent Application No. 62/436,587, filed Dec. 20, 2016, which is hereby incorporated by reference.

BACKGROUND

Trucks, tractor-trailers, and tractors connected to chassis carrying containers can be used to transport cargo that includes goods. Trucks, trailers, and containers typically have doors that can be opened to allow access to cargo that is being transported, and closed to secure the items.

BRIEF DESCRIPTION OF THE DRAWINGS

Some implementations of the present disclosure are described with respect to the following figures.

FIGS. 1A and 1B are schematic diagrams of a container hauled by a vehicle, the container including a door and a sensor device according to some examples mounted to the door.

FIG. 2A is a block diagram of a sensor device according to some examples.

FIG. 2B is a flow diagram of a motion detection process according to some examples.

FIG. 3A is a flow diagram of a process to determine an open/close status of a door that can be pivoted between an open position and a closed position, according to some examples where filters are not used to filter measurement data from a sensor device.

FIG. 3B is a flow diagram of a process to determine an open/close status of a door that can be pivoted between an open position and a closed position, according to further examples where multiple filters are used to filter measurement data from a sensor device.

FIGS. 4A-4C are graphs of various different data, according to some examples.

FIG. 5 is a flow diagram of a process to trigger activation of a rotation sensor, according to some examples.

FIG. 6 is a graph of a gyroscope active window according to some examples.

FIG. 7 is a flow diagram of a process to compute an open/close status of a door according to examples where filters are not used to filter measurement data from a sensor device.

FIGS. 8A-8B are a flow diagram of determining an open/close status of a door using a single filter, according to further examples.

FIGS. 9A-9B are a flow diagram of determining an open/close status of a door using multiple filters, according to additional examples.

FIG. 10 is a flow diagram of a process of detecting motion of a moveable platform, according to some examples.

FIG. 11 is a graph illustrating variance values as a function of time, for detecting motion of a moveable platform, according to some examples.

FIG. 12 is a flow diagram of a training process for computing stationary mean and variance values of acceleration data, according to further examples.

FIG. 13 is a flow diagram of a process of determining an open/close status of a door according to further examples.

Throughout the drawings, identical reference numbers designate similar, but not necessarily identical, elements. The figures are not necessarily to scale, and the size of some parts may be exaggerated to more clearly illustrate the example shown. Moreover, the drawings provide examples and/or implementations consistent with the description; however, the description is not limited to the examples and/or implementations provided in the drawings.

DETAILED DESCRIPTION

In the present disclosure, use of the term “a,” “an”, or “the” is intended to include the plural forms as well, unless the context clearly indicates otherwise. Also, the term “includes,” “including,” “comprises,” “comprising,” “have,” or “having” when used in this disclosure specifies the presence of the stated elements, but do not preclude the presence or addition of other elements.

A moveable platform can be used to carry physical items (such as cargo) between different geographic locations. Such moveable platforms can also be referred to as cargo transportation units (CTUs). For example, the moveable platform can be a container (that is attached to a tractor), a truck, or a trailer in which the physical items can be stored during shipment. In other examples, the moveable platform can include another type of carrier structure that is able to carry physical items. More generally, the moveable platform can be part of, mounted on, or attached to a vehicle, such as a truck, a tractor, a car, a railed vehicle (e.g., a train), a watercraft (e.g., a ship), an aircraft, a spacecraft, and so forth. It is noted that although the present discussion refers to a moveable platform as a container, techniques or mechanisms according to some implementations of the present disclosure are applicable to other cargo carrying platforms with an entry barrier that can be opened and closed.

In some cases, it may be desirable to determine whether or not a moveable platform is in motion. Depending on the types of sensors available, it may be challenging to detect motion of the moveable platform. For example, a sensor device on a moveable platform may include an accelerometer. Detecting motion using acceleration data from the accelerometer may be desirable in various example applications, such as to detect whether a door of the moveable platform is open or closed. To ensure accurate detection of the open/close status of the door, it may be desirable for open/close status detection process to be performed when the moveable platform is stationary. To do so, a determination is made of whether the moveable platform is in motion or not in motion. In other examples, motion detection of a moveable platform can be used for other applications.

The ensuing discussion refers to examples where motion detection is performed in the context of determining the open/close status of a door or other pivotable barrier. However, it is noted that motion detection using techniques or mechanisms according to some examples can be applied to other contexts.

The moveable platform can include a door through which physical items can be loaded or unloaded into or from an inner chamber of the moveable platform, respectively. The door is an example of an entry barrier (or more simply “barrier”) that can be opened and closed. Other examples of barriers include a window or any other structure that can be opened to allow entry through an opening, or closed to block entry through the opening.

In some cases, it may be desirable to detect when the barrier is in an open state or in a closed state. Due to movement of the moveable platform on which the barrier is mounted, it is possible for the orientation of the moveable platform to change as the moveable platform is moved to different locations. For example, at a first location, the moveable platform can be located on a relatively flat ground surface. However, at a second location, the moveable platform can be located on a slope.

Because the potential movement of the moveable platform can cause the orientation of the moveable platform to change (e.g., an angle of the moveable platform with respect to a horizontal plane can change), it may be challenging to determine an open/close status of the barrier using a single sensor. The “open/close status” of a barrier can refer to a status that indicates whether the barrier is in an open position or a closed position.

In accordance with some examples, techniques or mechanisms are provided to allow for the determination of the open/close status of a barrier that can be opened and closed (i.e., that can be moved between an open position and a closed position) irrespective of the orientation. The barrier is mounted on a moveable platform that is moveable between different geographic locations.

Typically, door opening and closing on a moveable platform is determined by a contact sensor (e.g., a Hall effect sensor) such that when the door is opened or closed the state change (contact made or broken) is detected by the contact sensor and communicated to a sensor device. This approach involves wiring the contact sensor to the sensor device. Moveable platforms can be subjected to rough handling with heavy cargo, and as a result, the wires between the contact sensor and the sensor device can easily be cut. Moreover, the additional wiring and installation adds cost.

FIG. 1A illustrates an example truck 100 that includes a tractor unit 102 and a container 104 (provided on a chassis) hauled by the tractor unit 102. FIG. 1B is a perspective view of the container 104. The container 104 is an example of a moveable platform that can be used to carry physical items. The container 104 includes a door 106 that is pivotable between an open position and a closed position. In FIGS. 1A-1B, the door 106 is in the open position.

The door 106 is pivotally mounted on hinges 116, which are attached to a frame 105 (referred to as “door frame”) of the container 104. The door 106 is able to rotate about the hinges 116 between the open position and the closed position. In FIG. 1A, two hinges 116 are shown. In other examples, the door 106 can be mounted on just one hinge, or on more than two hinges.

In accordance with some examples, a sensor device 108 is mounted to the door 106. The sensor device 108 can be mounted to an outer surface of the door 106 that faces the environment outside the container 104, or alternatively, the sensor device 108 can be mounted to an inner surface of the door 108 that faces into an inner chamber 110 of the container 104. In yet further examples, the sensor device 108 can be provided within a recess in the wall of the door 108.

The sensor device 108 can include sensors 112 and 114 and one or more processors 118. A processor can include any or some combination of the following: a microprocessor, a core of a multi-core microprocessor, a microcontroller, a programmable gate array, a programmable integrated circuit device, or another hardware processing circuit. Although the processor(s) 118 is depicted as being part of the sensor device 108 in some examples, it is noted that the processor(s) 118 can be separate from the sensor device 108 in other examples. More generally, sensors 112, 114 and the processor(s) 118 can either be integrated into the sensor device 108, such as on a circuit board or in an integrated circuit chip, or the sensors 112, 114 and the processor(s) 118 can be part of separate assemblies.

The sensor device 108 can also include a communication component to communicate over a network. In some examples, the sensor device 108 (along with other similar sensor devices arranged on barriers of other moveable platforms) can be part of a larger network of devices. This larger network of devices can be part of the “Internet-of-Things” (IoT) technology paradigm to allow different types of devices to communicate different types of data (including sensor data, voice data, video data, e-mail data, text messaging data, web browsing data, and so forth).

The ability of the sensor device 108 to communicate over a network can allow an entity (such as a distributor of goods, a manufacturer, or any other entity) to track assets of the entity as the assets are being transported throughout a geographic region.

In other examples, the sensor device 108 does not communicate data over a network.

Detecting the open/close status of the door 106 can be used to trigger various actions. For example, the sensor device 108 can send a notification (such as to a central service that is remotely located, or to the driver of the truck 100, or to another device on the truck 100) in response to detecting the door 106 in the open or closed position. Alternatively, the open/close status can be used to trigger measurement of other information (e.g., temperature, humidity, position of the container 104, or cargo load status, etc.), either by the sensor device 108 or by another sensor device. Other actions can be triggered by a detected open/close status in other examples.

The sensors of the sensor device 108 can include an accelerometer 112 and a rotation sensor 114. Although reference is made to an accelerometer or a rotation sensor in the singular sense, it is noted that techniques or mechanisms according to some implementations can be applied in other examples where there are multiple accelerometers and/or multiple rotation sensors that are part of the sensor device 108. The accelerometer 112 is used to measure acceleration along one or multiple axes, and can output acceleration data. The rotation sensor 114 is used to measure rotation about each of one or more axes. More specifically, the rotation sensor 114 can measure the rotation speed or rate of rotation about each respective axis.

In some examples, the rotation sensor 114 can include a gyroscope. In other examples, the rotation sensor 114 can include a rotation vector sensor, where a rotation vector produced by the rotation vector sensor represents the orientation of the rotation vector sensor as a combination of an angle and an axis, in which a device has been rotated through an angle around a specific axis.

Because the sensor device 108 is used to check the open/close status of a door that is mounted on a moveable platform, the rotation data from the gyroscope is used because comparing the acceleration data from the accelerometer against a threshold may not accurately determine the open/close status of the door, since the threshold that is used may not correspond to door movement depending upon the orientation of the frame (e.g., 105 in FIG. 1) on which the door is mounted. In other words, different thresholds may have to be used for different door frame orientations. Note also that parameters can be used for determining the open/close status of a door. Such parameters trained and learned for one door frame orientation may not be valid for a different orientation of the door frame.

Thus, according to some examples, since the door is mounted on a moveable platform whose position and orientation may change, the process for determining the open/close status of the door additionally uses rotation data from the gyroscope (or other rotation sensor) and further considers an orientation of the moveable platform.

In the ensuing discussion, reference is made to detecting the open/close status of a door, such as the door 106. It is noted that techniques or mechanisms according to some examples can be applied more generally to the detection of an open/close status of any type of barrier in other examples.

Sensor output can be noisy, where noise can come from a variety of different sources: mechanical vibration, electrical and thermal fluctuation, etc. As result, a processing technique to process sensor output for door status or motion status detection should account for the effect of noise for robust and accurate determination of door status or motion status.

A filter can be used to reduce noise in measurement data from a sensor device (e.g., 108 in FIGS. 1A and 1B). In a resource-constrained system like the sensor device 108 mounted on the moveable platform 104, it may be more desirable to use infinite impulse response (IIR) filters instead of finite impulse response (FIR) filters, since the storage load and computational complexity of IIR filters are typically lower than that of FIR filters.

An IIR filter can be described by using the following equation.

${{y\lbrack n\rbrack} = {{\sum\limits_{i = 0}^{N}\; {b_{i}{x\left\lbrack {n - i} \right\rbrack}}} + {\sum\limits_{j = 1}^{M}\; {a_{j}{y\left\lbrack {n - j} \right\rbrack}}}}},$

where y [n] denote the filter output at time point n, x[n−i] denote the filter input at time point n−i, b_(i) is called the i-th feedforward coefficient, and a_(j) is called the j-th feedback coefficient. In the above, N is called the feedforward filter order and M is called the feedback filter order. When N=M=1 and a₁+b₀=1, a simple IIR filter can be defined by a single parameter a₁,

y[n]=(1−a ₁)x[n]+a ₁ y[n−1].

Expanding the above equation, it is seen that for any 0<a₁<1, the impact of x[n−i] on y[n] decreases exponentially as the time distance i from the time point n grows, i.e.,

$\begin{matrix} {{y\lbrack n\rbrack} = {{\left( {1 - a_{1}} \right){x\lbrack n\rbrack}} + {a_{1}{y\left\lbrack {n - 1} \right\rbrack}}}} \\ {= {{\left( {1 - a_{1}} \right){x\lbrack n\rbrack}} + {{a_{1}\left( {1 - a_{1}} \right)}{x\left\lbrack {n - 1} \right\rbrack}} + {a_{1}^{2}{y\left\lbrack {n - 2} \right\rbrack}}}} \\ {= {{\left( {1 - a_{1}} \right){x\lbrack n\rbrack}} + {{a_{1}\left( {1 - a_{1}} \right)}{x\left\lbrack {n - 1} \right\rbrack}} + \ldots +}} \\ {{{{a_{1}^{i}\left( {1 - a_{1}} \right)}{x\left\lbrack {n - i} \right\rbrack}} + {a_{1}^{i + 1}{{y\left\lbrack {n - i - 1} \right\rbrack}.}}}} \end{matrix}$

Thus, a large impulse x[n] will have a longer impact on the filter output for a filter whose coefficient a₁ is large than for a filter whose coefficient a₁ is small. For this reason, a filter with a larger coefficient a₁ may be referred to as a long filter, and a filter with a smaller coefficient a₁ can be referred to as a short filter. Due to their respective constructions, note that:

a long filter is less sensitive to local changes than a short filter; and

a short filter is faster to adapt to change in statistics than a long filter.

Stated differently, an impact of an input, x[n−i], at a previous time point on an output, y[n], of the long filter is greater than an impact of the input at the previous time point on an output of the short filter.

In accordance with some implementations of the present disclosure, door status detection systems and techniques can satisfy the following conditions C1 and C2. As explained further below, to address noisy measurement data from a sensor device, filters can be used that consider both conditions C1 and C2.

-   C1. A door status detection system or technique has to be fast and     responsive so that the probability of missing a true door event is     low; and -   C2. The door status detection system or technique is expected to be     robust and reliable so that the probability of reporting a false     event (falsely reporting a door as open when the door is closed, or     falsely reporting the door as closed when the door is open) is low.

Note that door status detection is to be disabled when the moveable platform is detected to be in motion. As such, door status detection depends upon motion detection.

In practice, even when a door is in a closed position, it may be subject to environmental disruptions like strong winds. In addition, the moveable platform itself may be in harsh environments like an open sea where movement can be unpredictable. With these in mind, it is desirable to consider condition C2 in designing and developing solutions for door status detection.

In FIG. 1B, three axes are defined: X, Y, and Z. In the view of FIG. 1B, the X axis points generally upwardly, which in the view of FIG. 1B is generally parallel with a rotation axis of each hinge 116. The door 106 is rotatable about the rotation axis of the hinge 116. The Y axis is a radial axis that is perpendicular to the X axis (where the X axis is also referred to as a vertical or gravitational axis). In the view shown in FIG. 1B, the Y axis is parallel to the main surface of the door 106 and points towards the hinges 116. The Z axis (also referred to as a tangential axis) is in a direction that is normal to the main surface of the door 106; when the door 106 is in the closed position, the Z axis points into the inner chamber 110 of the container 104.

Although reference is made to the X axis as pointing upwardly in the view shown in FIG. 1B, it is noted that in other examples, the X axis can point in a different direction. More generally, the X axis is parallel to the rotation axis of a hinge about which the door 106 is rotatably mounted. Thus, in a different example, a hinge of the door 106 can be mounted such that its rotation axis extends along a horizontal axis, or along a diagonal axis. In other examples, rolling doors that move up and down do not have hinges but have rollers or other mechanisms to move up and down.

In some examples, the accelerometer 112 can measure acceleration along each of the X, Y, and Z axes, and the rotation sensor 114 can measure rotation data about each of the X, Y, and Z axes. In other examples, the accelerometer 112 can measure acceleration in a subset of the X, Y, and Z axes, such as along the X and Y axes, and the rotation sensor 114 can measure rotation data about just the X axis.

An example of the sensor device 108 is shown in FIG. 2A. The sensor device 108 includes the accelerometer 112, the rotation sensor 114, and the one or more processors 118. The sensor device 108 can be implemented as a circuit board on which are mounted the accelerometer 112, the rotation sensor 114, and the processor(s) 118 plus associated memory and circuits, all housed in a suitable enclosure. In other examples, the sensor device 108 can be implemented as an integrated circuit chip with the accelerometer 112, the rotation sensor 114, and the processor(s) 118 plus associated memory and circuits, all housed in a suitable enclosure. In yet further examples, the processor(s) 118 can be separate from an assembly including the sensors 112 and 114.

The processor(s) 118 can receive acceleration data from the accelerometer 112, and rotation data from the rotation sensor 114.

The sensor device 108 further includes a storage medium 206 that stores a motion detection module 208 (which can include machine-readable instructions such as software or firmware) to detect motion of the moveable platform 104, and a door status detection module 210 (which can include machine-readable instructions such as software or firmware) to determine an open/close status of the door 106. Each of the motion detection module 208 and the door status detection module 210 is executable on the processor(s) 118. Although examples refer to the motion detection module 208 and/or the door status detection module 210 implemented as machine-readable instructions executable on processor(s), in other examples, the motion detection module 208 and/or the door status detection module 210 can be implemented with just a hardware processing circuit.

The motion detection module 208 uses the acceleration data from the accelerometer 112 to determine motion of the moveable platform 106 in accordance with some implementations of the present disclosure.

The door status detection module 210 uses the acceleration data from the accelerometer 112 and the rotation data from the rotation sensor 114 to determine the open/close status of the door 106.

A communication component 202 can transmit an output indication 204 to a destination over a data network. The output indication 204 can be in the form of a message, an information field in a message, or other indicator.

The output indication 204 can be a motion indicator to indicate whether or not the moveable platform 104 is in motion. For example, if the motion indicator is set to a first value, that indicates that the moveable platform 104 is in motion. However, if the motion indicator is set to a second value, that indicates that the moveable platform 104 is not in motion.

In further examples, the motion indicator is not output by the sensor device 108. Rather, the motion indicator is communicated by the motion detection module 208 to the door status detection module 210 for use by the door status detection module 210 in triggering a process to detect the open/close status of the door 106.

In additional examples, the output indication 204 can include an open/close status indicator to indicate whether the door 106 is open or closed. The open/close status indicator if set to a first value indicates that the door 106 is open, and if set to a second value indicates that the door 106 is closed.

The communication component 202 can include a wireless transceiver and associated circuits to allow for wireless communication by the sensor device 108 to the data network. The wireless communication can include wireless communication over a cellular access network, a wireless local area network, a satellite network, and so forth.

Alternatively, the communication component 202 can include a wired transceiver and associated circuits to perform wired communications between the sensor device 108 and the destination. More generally, the communication component 202 includes a communication transceiver and associated circuits.

The destination to which the output indication 204 is sent can include a server or a collection of servers and associated network equipment which may be located at one fixed location or in a mobile unit or as part of a data center or cloud.

In further examples, instead of communicating the output indication 204 to a destination device that is external of the sensor device 108, the output indication 204 can instead be used internally in the sensor device 108 to trigger an action, such as to cause other sensor(s) (not shown) of the sensor device 108 to measure one or more parameters or to take another action.

FIG. 2B is a flow diagram of a motion detection process according to some examples to detect the motion of the moveable platform 104. The motion detection process can be performed by the motion detection module 208 of FIG. 2A, for example. The motion detection process includes computing (at 220) a variance based on acceleration data from the accelerometer 112. The motion detection process further determines (at 222), using the computed variance, whether the moveable platform 106 is in motion. Further details of the motion detection process are provided below.

In the ensuing discussion, reference is made to examples where the rotation sensor 114 includes a gyroscope. In other examples, it is noted that techniques or mechanisms according to some implementations can be applied with other types of rotation sensors.

A gyroscope may consume a relatively large amount of power, in some cases greater than the power consumed by an accelerometer, for example. As such, it is desirable to maintain the gyroscope in a low power state, until the gyroscope is to be used for measuring rotation data. A low power state can refer to a state of the gyroscope where the gyroscope is powered off, or where some portion of the gyroscope is powered off to reduce power consumption by the gyroscope. The gyroscope can be activated to transition the gyroscope from the lower power state to an operational state, where the operational state of the gyroscope refers to a state of the gyroscope where the gyroscope can measure rotation data and output the rotation data.

FIG. 3A is a flow diagram of a general door open/close (DOC) process of determining an open/close status of a door (e.g., the door 106) mounted on a moveable platform (e.g., the container 104). The DOC process of FIG. 3A does not use filters to filter measurement data from the sensor device 108.

The DOC process of FIG. 3A can be performed by a computing device, such as by the processor(s) 118 according to some examples. The DOC process of FIG. 3A can receive (at 302) acceleration data from an accelerometer, such as the accelerometer 112 that is part of the sensor device 108 mounted on the door. The DOC process can determine (at 304) whether to activate a gyroscope (e.g., 114 in FIG. 1B or 2) based on the acceleration data from the accelerometer, where activating the gyroscope refers to transitioning the gyroscope from the low power state to the operational state.

If the gyroscope is not to be activated, then the DOC process can continue to receive further acceleration data from the accelerometer. However, if it is determined that the gyroscope is to be activated, then the DOC process can cause activation (at 306) of the gyroscope. The DOC process receives (at 308) rotation data from the activated gyroscope.

The DOC process of FIG. 3A further includes determining (at 310) an open/close status of the door based on the rotation data from the gyroscope (and possibly also on the acceleration data from the accelerometer). It is noted that the determined open/close status of the door also accounts for the orientation of the moveable platform on which the door is mounted, where the orientation can change as a result of the moveable platform moving to different locations.

In some implementations, the DOC process can be disabled when the moveable platform is detected to be in motion. Detecting motion of the moveable platform can be based on any or some combination of the following: the acceleration data from the accelerometer 112, based on positioning information from a global positioning system (GPS) receiver, based on speed information provided by the vehicle, and so forth. In response to detecting that the moveable platform is in motion, the DOC process deactivates determination of the open/close status of the door.

Although rotation data from the gyroscope can detect door opening with relatively high reliability, detecting door closing is analogous to proving a negative. As a result, the DOC process according to some implementations can use both the rotation data from the gyroscope and the acceleration data from the accelerometer under certain conditions to improve reliability in detecting door closing.

In further examples, a DOC process (that does not use filters to filter measurement data from the sensor device 108) can follow the procedure below.

-   -   S1. Monitor the tangential component (along the Z axis) of the         acceleration data (hereinafter referred to as the “tangential         acceleration data”) from the accelerometer. If a substantial         jump in the tangential acceleration data is detected (based on         determining if a variance of the tangential acceleration data         satisfies specified conditions G1 and G2 as discussed further         below), the procedure continues to S2.     -   S2. Activate the gyroscope to track the angle movement around         the X axis (vertical or gravitational axis).         -   a. If the angle movement is away from the door frame and the             turned angle is large enough (e.g., as determined according             to FIG. 7 discussed further below), a door open event is             reported;         -   b. If the angle movement is small, the procedure continues             to S3.     -   S3. Check if the tangential acceleration data of the         acceleration is stable and close to a bias trained when the door         is closed and at a stationary position (e.g., as determined         according to FIG. 7). If the answer is yes, a door close event         is reported.

As noted above, to compensate for noisy measurements from a sensor, such as the accelerometer 112, a filter, such as an IIR filter, can be applied. A filter can be used to filter acceleration data from the accelerometer 112 during both a training process (to train the system or technique for detecting the open/close status of a barrier) and a detection process (to detect the open/door status of a barrier). However, use of a single filter, such as a single IIR filter, may not adequately address conditions C1 and C2 above.

To meet condition C1, a short filter may be preferred. However, to meet condition C2, a long filter may be preferred. As a result, if just one IIR filter is used, a dilemma may arise in selecting an optimal IIR filter to address conditions C1 and C2, which can result in a trade-off between a door status detection solution that is fast and responsive or that is robust and reliable.

In accordance with some implementations of the present disclosure, a DOC process can determine an open/close status of a door (or other pivotable barrier) on a moveable platform based on selective use of a plurality of different filters (e.g., selective use of a short filter and a long filter) for filtering measurement data from a sensor device (e.g., 108 in FIG. 1B or 2).

As shown in FIG. 3B, the DOC process according to some implementations can attempt (at 320) to determine an open/close status of the door based on first filtered measurement data from the sensor device filtered using a first filter (e.g., the short filter). In response to determining that the open/close status is not successfully determined based on the first filtered measurement data, the DOC process determines (at 322) the open/close status of the door based on second filtered measurement data from the sensor device filtered using a second filter (e.g. the long filter) different from the first filter.

The following assumes that the accelerometer 112 is a three-axis accelerometer that can measure acceleration data in each of the X, Y, and Z axes, and that the gyroscope 114 is a three-axis gyroscope that can measure rotation data about each of the X, Y, and Z axes. However, in other examples, the acceleroemter 112 and the gyroscope 114 can measure respective measurement data for a smaller number of axes. For example, the accelerometer can measure acceleration data along only the Y and Z axes, and the gyroscope can measure rotation data about only the X axis.

The acceleration data from the accelerometer 112 includes radial acceleration data (along the Y axis), tangential acceleration data (along the Z axis), and gravitational acceleration data (along the X axis), which are denoted respectively by r₁r₂ . . . (radial acceleration data), t₁t₂ . . . (tangential acceleration data), and v₁v₂ . . . (gravitational acceleration data). The rotation data from the gyroscope 114 includes rotation data about the X axis, Y axis, and Z axis, which are denoted a g_(x,1)g_(x,2) . . . g_(y,1)g_(y,2) . . . , and g_(z,1)g_(z,2) . . . , respectively.

The gyroscope is to remain inactive until it is activated. In some implementations, once activated, the gyroscope can operate for a specified time duration, during which the gyroscope is able to measure rotation data. In response to expiration of the specified time duration, the gyroscope is deactivated to reduce power consumption.

The output of the DOC process includes an open/close indication e_(i) at time point i, where e_(i) can be set by the DOC process to one of multiple different values, such as:

e_(i)=0 indicates no door movement,

e_(i)=1 indicates door closing movement (door closed status), and

e_(i)=−1 indicates door opening movement (door open status).

Although specific values of e_(i) are provided above, it is noted that in other examples, e_(i) can be set to different values to indicate different door status.

A door opening movement is characterized by the door opening by at least a specified angle (e.g., 8°, 10°, etc.) during the specified duration of operation of the gyroscope, in response to a detectable force.

A door closing movement is characterized by the door hitting the door frame with a detectable force and remaining stationary at the door frame for at least a second time duration, such as a fractional end portion of the specified time duration of operation of the gyroscope.

In some examples, the DOC process outputs a sequence e₁e₂ . . . , e_(N), where N>1, for respective time points 1, 2, . . . , N, and each e_(i) at time point i can have one of the three example values noted above.

The accelerometer and gyroscope can be sampled at the same frequency f_(s), such as 50 Hertz (Hz) or a different frequency.

FIGS. 4A-4C are three graphs that depict rotation data (FIG. 4A), tangential acceleration data (FIG. 4B), and the open/close status (FIG. 4C) as a function of time. A curve 402 in FIG. 4A depicts gyroscope rotation data about the X axis at respective time points. A curve 404 in FIG. 4B represents tangential acceleration data about the Z axis from the accelerometer at respective time points. A curve 406 represents a result of the open/close determination performed by the DOC process according to some examples. FIG. 4C also shows a ground truth curve 408 that indicates the actual open/close status of the door. The ground truth curve 408 being below value zero indicates that the door is closed, while the ground truth curve 408 being below zero indicates that the door is closed. As indicated by the ground truth curve 408, the door starts in the closed position, is moved to the open position, and is then moved to the closed position. In the example shown in FIG. 4C, as indicated by the ground truth curve 408, a door opening sequence is centered at time T1, while a door closing sequence is centered at time T2.

An upward spike 410 of the curve 406 in FIG. 4C indicates a door open status, while a downward spike 412 of the curve 404 indicates a door close status.

In general, the DOC process according to some examples of the present disclosure includes two sub-processes: (1) determining whether to activate the gyroscope based on the acceleration data from the accelerometer, and (2) determining the open/close status of the door based on the gyroscope data and possibly the acceleration data.

Triggering Activation of the Gyroscope

The following describes the sub-process in the DOC process for triggering activation of the gyroscope 114, based on acceleration data from the accelerometer 112. Generally, in some examples, the triggering of the activation of the gyroscope can be based on a variance of the acceleration data. Variance can refer to the expectation of the squared deviation of a random variable (in this case acceleration data) from its mean. The DOC process can determine whether the computed variance satisfies one or more conditions, and if so, that is an indication that the door may be moving and thus the gyroscope should be activated to perform the determination of the open/close status of the door.

For simplicity, in the following discussion, it is assumed that the DOC process uses just the tangential acceleration data t₁t₂ . . . (along the Z axis) from the accelerometer to determine whether the gyroscope is to be activated or not. In other examples, the acceleration data along one or more of the X axis and Y axis can be used to determine whether the gyroscope is to be activated or not.

At time point i, the DOC process computes a gyroscope activation indication, gi_(i), as follows:

gi_(i)=1 indicates that the gyroscope is to be activated; and

gi_(i)=0 indicates that the gyroscope is not to be activated.

Although specific values for g_(i) are noted above, it is contemplated that the gyroscope activation indication g_(i) can have other values in other examples for indicating whether or not the gyroscope is to be activated.

FIG. 5 is a flow diagram of an example process to control activation of the gyroscope that is initially in a low power state. The process of FIG. 5 can be performed by the processor(s) 118 of FIGS. 1B and 2, or by a different computing device. In the following discussion, μ_(t,i) represents the mean of the tangential acceleration data t₁t₂ . . . at each time point i, while σ_(t,i) ² represents the variance of the tangential acceleration data t₁t₂ . . . at each time point i. The process of FIG. 5 computes (at 502) the mean and variance parameters (μ_(t,i), σ_(t,i) ²) according to:

$\begin{matrix} {{\mu_{t,i} = \frac{S_{t,i}}{K}},} & \left( {{Eq}.\mspace{14mu} 1} \right) \\ {{\sigma_{t,i}^{2} = {\frac{S_{t^{2},i}}{K} - \mu_{t,i}^{2}}},} & \left( {{Eq}.\mspace{14mu} 2} \right) \\ {where} & \; \\ {{S_{t,i} = {\sum\limits_{j = {i - K + 1}}^{i}t_{j}}},} & \left( {{Eq}.\mspace{14mu} 3} \right) \\ {S_{t^{2},i} = {\sum\limits_{j = {i - K + 1}}^{i}{t_{j}^{2}.}}} & \left( {{Eq}.\mspace{14mu} 4} \right) \end{matrix}$

In Eqs. 1-4, the parameter K is a specified constant value that represents a time window size in terms of number of samples (at respective time points) of the tangential acceleration data over which the respective mean and variance are computed, where each sample is collected at a respective time point.

More generally, Eq. 3 sums the tangential acceleration data t₁t₂ . . . from time point j=i−K+1 to a current time point i to compute S_(t,i), and Eq. 4 sums the square of the tangential acceleration data t₁t₂ . . . from time point j=i−K+1 to a current time point i to compute S_(t) ₂ _(,i). The values S_(t,i) and S_(t) ₂ _(,i) are used in Eqs. 1 and 2, respectively, to compute the mean μ_(t,i) and the variance σ_(t,i) ².

The process sets (at 504) gi_(i)=0 (gyroscope inactive).

The process determines (at 506) if one or more of specified conditions G1 and G2 are satisfied, where

σ_(t,i) ² >C ₁σ_(t,i−K) ²,  Condition G1:

σ_(t,i) ² >C ₂.  Condition G2:

Condition G1 relates to whether the variance σ_(t,i) ² computed according to Eq. 2 is greater than C₁σ_(t,i−K) ², where C₁ is a specified constant value. Condition G1 includes a comparison of a current variance σ_(t,i) ² at time point i with a value based on a product of the constant C₁ and the variance σ_(t,i−K) ² computed at the beginning of the time window at i−K.

Condition G2 relates to a determination of whether a current variance σ_(t,i) ² at time point i is greater than a threshold C₂, which is a specified constant value.

In the foregoing computations, the constants C₁ and C₂ are used to determine if the force used to generate tangential movement is significant enough in that it may be due to door opening or closing. The values of K, C₁, and C₂ can be empirically set based on past experience and the specific characteristics of the sensor device and the door whose open/close status is to be determined. In some examples, K=25, C1=16, and C2=0.6. However, in other examples, other values of K, C₁, and C₂ can be used. For example, C₂ may be determined by statistics, e.g., variance, from accelerometer readings from other axes, e.g., the X axis, the Y axis, or a combination of both X and Y axes. Note that the variance of acceleration along the X axis is often used to determine whether the platform on which the door is mounted, e.g., a container or a trailer, is moving or not. C₂ as a function of the variance of acceleration along the X axis essentially indicates that G2 is conditioned upon the movement of the platform.

If either condition G1 or G2 is satisfied, then the process sets (at 508) gi_(i)=1, to cause activation of the gyroscope. However, if neither condition G1 nor G2 is satisfied, then the process maintains gi_(i)=0 and returns to task 502.

In further examples, in task 502, the variance σ_(t,i) ² may be multiplied by

$\frac{K}{K - 1}$

to obtain an unbiased sample variance. Furthermore, S_(t,i) in Eq. 3 may be efficiently computed from S_(t,i−1) by using the following equation.

S _(t,i) =S _(t,i−1) −t _(i−K) +t _(i).  (Eq. 5)

Similarly, S_(t) ₂ _(,i) in Eq. 4 may be efficiently computed from S_(t) ₂ _(,i−1) by using

S _(t) ₂ _(,i) =S _(t) ₂ _(,i−1) −t _(i−K) ² +t _(i) ².  (Eq. 6)

In alternative examples, μ_(t,i) and σ_(t,i) ² in task 502 may be approximated by using IIR filters. Let a denote an IIR filter parameter. Then

μ _(t,i)=(1−α)μ _(t,i−1) +αt _(i),  (Eq. 7)

S _(t,i)=(1−α) S _(t,i−1) +αt _(i),  (Eq. 8)

σ _(t,i) ² =S _(t,i)−μ _(t,i).  (Eq. 9)

In such alternative examples, the FIG. 5 process can be modified to use the variance σ _(t,i) ² computed according to Eq. 9 rather than the variance σ_(t,i) ² computed according to Eq. 2.

Also, tasks 506 and 508 can be modified to detect if conditions G1 and G2 are consistently met over a number of consecutive samples to reduce false positives. In other words, rather than set gi_(i)=1 when condition G1 or G2 is satisfied for time point i, the setting of gi_(i)=1 is based on whether the condition G1 or G2 is also satisfied over the next number of time points. In the case where IIR filters are used, the threshold on the number of samples over which conditions G1 and G2 are evaluated may be adaptive to σ_(t,i) ²—the larger σ_(t,i) ² is observed, the higher the threshold is, reflecting the fact that the IIR filters have longer tails for larger values.

Detecting Open/Close Status of the Door

The following process describes how the open/close status of the door is determined, based on rotation data from the gyroscope. It is noted that in some cases, the closed status of the door may not be determined with just the rotation data; in such cases, acceleration data would also be used.

Once the gyroscope is triggered at time point i in response to setting gi_(i)=1 (task 508 in FIG. 5), the gyroscope remains active for a specified time duration (e.g., three seconds or some other time duration). The reason that the gyroscope stays on for the specified time duration is to ensure that the gyroscope returns to a low power state after the rotation data measurements have been made in the specified time duration. In some examples, at a sampling frequency f_(s)=50 Hz, assuming a three-second time duration when the gyroscope is activated, a total of 150 rotation data samples from the gyroscope are collected for use in detecting door opening and closing. In other examples, different time durations and different sampling frequencies can be used.

In the ensuing discussion, the time duration during which the gyroscope is activated to collect rotation data is referred to as the “gyroscope active window,” shown as 602 in FIG. 6. In FIG. 6, each upwardly pointing arrow represents a rotation data sample collected at a respective time point by the gyroscope.

Since door movement in some examples involves rotation along the X axis, the DOC process uses just the gyroscope's rotation data about the X axis, g_(x,i)g_(x,i+1) . . . g_(x,i+149) (assuming that 150 samples of rotation data are collected in the gyroscope active window 602).

Let j=i+149, where j represents the end of the gyroscope active window 602, and i represents the beginning of the gyroscope active window. The DOC process computes the open/close indication e_(j) based on rotation data samples g_(x,i)g_(x,i+1) . . . g_(x,j) (from time point i to time point j) according to the process shown in FIG. 7. As noted above, the open/close indication e_(j) can be set to one of three values (−1 to indicate door open, 1 to indicate door close, and 0 to indicate otherwise).

Note that the process of FIG. 7 does not use filters to filter measurement data from the sensor device 108.

Task 702: In some examples, the process finds the smallest time point k (in the time range from time point i to time point j) where a rotation data sample g_(x,k) indicates that the door is rotating away from the door frame (e.g., 105 in FIG. 1B). Note that the door is rotating away from the door frame if g_(x,k)>0. Stated differently, this task involves finding the index k such that g_(x,k)≥0, i≤k<j, and denoting this smallest index k by k*. If no such k exists, set k*=j+1.

In other examples, instead of finding the smallest time point k, the process may choose, for example, to save computational complexity, to find a time point k where a rotation data sample g_(x,k) indicates that the door is rotating away from the door frame.

Task 704: The process computes an angle of rotation of the door away from the door frame by computing an approximate integration of the rotation data samples from the gyroscope, in the time range from time point k* to time point j. The approximate integration of the rotation data is computed as

a _(j)=Σ_(k=k*) ^(j) g _(x,k), if If k*≤j,

a _(j)=0 if k*>j.  (Eq. 10)

In Eq. 10 above, a_(j) is produced by aggregating (e.g., summing) the rotation data samples, which produces an aggregate value, a_(j), that represents an approximation of the rotation angle of movement of the door (i.e., how many degrees the door has rotated about the X axis).

Task 706: The process computes a number of samples of the rotation data (g_(x,k)) indicating that the door is rotating away from the door frame, in a fractional end portion (604 shown in FIG. 6) of the gyroscope active window 602. In the case of a door close event, the number of samples of the rotation data indicating that the door is opening in the fractional end portion 604 should be less than some specified threshold. Even when the door has hit the door frame when being closed, vibration of the door due to the elasticity of the door can cause some rotation data samples in the fractional end portion 604 of the gyroscope active window 602 to be greater than zero (to indicate movement away from the door frame). More specifically, this number of samples of the rotation data indicating that the door is opening in the fractional end portion 604 is expressed as

n=|{k:|g _(x,k)|>0.2,j−f _(s)/2≤k≤j}|.  (Eq. 11).

In Eq. 11, j−f_(s)/2≤k≤j corresponds to the duration of the fractional end portion 604, which starts at j f_(s)/2 and ends at j.

Task 708: The process computes the open/close indication e_(j) as follows.

e _(j)=−1 if a _(j) >C3,

e _(j)=1 if a _(j) <C4 and n _(j) ≤C5,

e _(j)=0 otherwise

The open/close indication e_(j) is computed based on comparing the angle of rotation of the door away from the door frame (a_(j)) with respect to thresholds C3 and C4, and based on comparing n_(j) to the threshold C5.

The parameters C3, C4, and C5 are specified constants. The parameter C3 represents a threshold amount of rotation angle (e.g., 8°, 10°, etc.) that the door has to rotate in a direction away from the door frame to indicate that the door has moved to the open position. For example, C3 is set to 8 to indicate 8°, set to 10 to indicate 10°, and so forth. Thus, a_(j)>C3 indicates that the door has rotated away from the door frame by more than C3 degrees.

The parameter C4 represents a threshold amount of rotation angle (e.g., 3°, etc.) that a_(j) should be less than to indicate that the door has possibly moved to the closed position.

Thus, generally, the DOC process determines that the door has moved to the open position in response to the aggregate value, a_(j), having a specified relation with respect to a first threshold (e.g., a_(j)>C3). The DOC process determines that the door has moved to the closed position in response to the aggregate value, a_(j), having a specified relationship with respect to a second threshold (e.g., a_(j)<C4), and further based on another condition that confirms the door closed status (e.g., n_(j)≤C5).

The parameter C5 (e.g., 2, etc.) represents a threshold number of samples of rotation data exceeding zero (to indicate rotation away from the door frame) used to confirm a door close event. Thus, n_(j)≤C5 specifies that the number of samples of rotation data indicating that the door is opening in the fractional end portion 604 is less than or equal to C5. More generally, n_(j) is a stationary indication value (a bias) for indicating whether the door is stationary (e.g., n_(j)≤C5 indicates that the door is stationary). If both a_(j)<C4 and n_(j)≤C5 are true, then a door close status is confirmed, and e_(j) is set to 1.

However, if a_(j)<C4 but n_(j)>C5, the door may still be in the middle of a closing sequence before stopping. In view of this, the DOC process can continue checking (for up to 5 seconds or another time duration, for example) if the tangential acceleration data t_(j+1)t_(j+2) . . . , and the radial acceleration data r_(j+1)r_(j+2) . . . converge to stationary values estimated when the door is still and closed. If convergence of the tangential acceleration data and the radial acceleration data is detected at time point j′>j, then the DOC process sets e_(j′)=1.

Thus, a determination of a closed status of the door under the condition that a_(j)<C4 but n_(j)>C5 is based on the rotation data from the gyroscope and a determined convergence that is based on the orientation of the moveable platform on which the door is mounted. More specifically, the determination of the closed status of the door is based on the rotation data and convergence of the acceleration data that is based on the orientation of the moveable platform.

The convergence of tangential acceleration data and radial acceleration data is discussed further below.

Use of IIR Filters for Door Open/Close Status Detection

To compensate for noise in measurement data from the acceleration data when determining the open/close status of a barrier, FIGS. 8A-8B illustrate a procedure according to examples where just one IIR filter is used. Note that the biases used in determining whether the door is closed or not based on tangential acceleration data are learned by using learning techniques discussed further below.

As noted above, use of just one IIR filter may not adequately satisfy both conditions C1 and C2 discussed further above.

FIGS. 8A-8B depict an iterative procedure that iterates over multiple time points i.

Task 802: The procedure increments time point i.

Task 804: The procedure receives acceleration data (t_(i), r_(i), v_(i)) from the accelerometer.

Task 806: The procedure filters each component in the acceleration data (t_(i), r_(i), v_(i)) by using the IIR filter to obtain filtered output including filtered acceleration (t′_(i), r′_(i), v∝_(i)). Variances (σ_(t,i) ², σ_(r,i) ², σ_(v,i) ²) are estimated based on the acceleration data (t_(i), r_(i), v_(i)).

Task 808: The procedure determines if the gyroscope is activated.

Task 810: If the gyroscope is activated, the procedure receives rotation data g_(x,i) (rotation data about the X axis at time point i) from the gyroscope.

Task 812: The procedure determines if the elapsed time (i−i*) is greater than or equal to T_(G), which represents the time duration during which the gyroscope is activated before placing the gyroscope to sleep. The parameter i* represents the time point at which the gyroscope was activated. In some examples, T_(G) can be set to 3f_(s), i.e., three times the sampling frequency f_(s), which is equivalent to 3 seconds. In other examples, other values of T_(G) can be used. If the elapsed time (i−i*) is not greater than or equal to T_(G), then the process increments i (task 802) and continues to receive additional acceleration and rotation data.

Task 814: If the elapsed time (i−i*) is greater than or equal to T_(G), then the procedure places the gyroscope in sleep mode. An amount of rotation, θ_(t), of the door is computed from g_(x,i), g_(x,i−i) . . . , g_(x,i*), such as according to Eq. 10 above.

Task 816: The procedure determines if B_(i) is greater than or equal to θ_(open) (which is a specified threshold representing an amount of rotation indicating that the door has been opened). If θ_(i) is not greater than or equal to θ_(open), then the process returns to task 802 (the door status remains indicated as closed).

Task 818: If θ_(i) is greater than or equal to θ_(open), then the procedure changes the door status to “Open.” The procedure can send an indication of the open status to a target entity.

Task 820: If the determination at task 808 indicates that the gyroscope is not activated, then the procedure determines whether a parameter useAccelForDoorDecision is set to True. If so, that indicates that acceleration data is to be used for determining whether the door is closed.

Task 822: If the parameter useAccelForDoorDecision is not set to True, then the procedure determines, based on variance data σ_(t,i) ² . . . σ_(t,i−K) ² (computed from tangential acceleration data in task 806), whether there is a possible door event. K represents a size of a time window over which a determination is to be made regarding whether a possible door event should trigger activation of the gyroscope. If it is determined there is not a possible door event, then the process returns to task 802. The determination if there is a possible door event based on σ_(t,i) ² . . . σ_(t,i−K) ² may involve the following:

-   -   Compute n_(t)=|{i≤j<i−K:|σ_(t,i) ²|>L_(t)}|, where L_(t) is a         threshold to determine whether the variance is significant and         possibly due to door movement. L_(t) may depend upon the         sampling frequency f_(s). An example value of L_(t) is 0.6 when         f_(s)=50 Hz. Other values of L_(t) can be used in other         examples.     -   If n_(t)>C_(t), where C_(t) is a specified threshold depending         upon f_(s), then it is likely there is a possible door event. In         the above, C_(t) may be set to 3 when f_(s)=50 Hz, in some         examples. Other values of C_(t) can be used in other examples.

Task 824: If it is determined at task 822 that there is a possible door event, then the procedure activates the gyroscope, and the procedure sets i*=i (to indicate the time point at which he gyroscope was activated).

Task 826: If the parameter useAccelForDoorDecision is set to True (as determined at 820), then the procedure sets the parameter useAccelForDoorDecision to True, and sets {circumflex over (ι)}=i. Also, the procedure computes a threshold T_(A) based on g_(x,i), g_(x,i−1) . . . , g_(x,i*). T_(A) is used to control how long the accelerometer is to be used to determine whether the door is in a closed position. T_(A) may be determined by g_(x,i), g_(x,i−1) . . . , g_(x,i*)as follows. Let G denote a specified threshold that depends upon f_(s), e.g., G=f_(s).

-   -   Compute n_(G)=|{i≤j<i−G: |a_(i)|>L_(G)}| from g_(x,i), g_(x,i−1)         . . . , g_(x,i−G+1), where L_(G) is a threshold set according to         the gyroscope's typical readings in a stationary position         without movement. An example value of L_(G) is 0.2. Other values         of L_(G) can be used in other examples.     -   If n_(G)>C_(G), where C_(G) is a specified threshold depending         upon f_(s), then it is likely that the gyroscope is not yet         stabilized due to door movement. As a result, T_(A) is set to a         larger value, e.g., 20f_(s), otherwise, since the gyroscope is         stabilized, T_(A) is set to a smaller value, e.g., 15f_(s). In         the above, C_(G) may be set to 3 when f_(s)=50 Hz. Other values         of C_(G) can be used in other examples.

Task 828: The procedure determines if the elapsed time (i−{circumflex over (ι)}) is greater than or equal to T_(A). If not, the process returns to task 802.

Task 830: If the elapsed time (i−{circumflex over (ι)}) is greater than or equal to T_(A), then the procedure determines based on the filtered tangential acceleration data t′_(i)t′_(i−1) . . . t′_({circumflex over (ι)}) if the door is in the closed position. If not, then the process returns to task 802.

Task 832: If it is determined at task 830 that the door is in the closed position, then the procedure changes the door status to “Closed,” and can send an indication of the closed status to a target entity.

Use of Multiple Filters

The foregoing procedure of FIGS. 8A-8B uses a single IIR filter to filter acceleration data.

In some implementations of the present disclosure, multiple different filters can be used to filter acceleration data, to address the dilemma when selecting a single IIR filter to meet both conditions C1 and C2 can be difficult or sub-optimal.

The following solution uses two filters (a short filter and a long filter) to perform door status detection.

-   -   S1. Monitor the tangential acceleration data from the         accelerometer. If a substantial jump in the tangential         acceleration data is detected, continue to S2.     -   S2. Activate the gyroscope to track the angle movement.         -   a. If the angle movement is away from the door frame and the             turned angle is large enough, a door open event is reported;         -   b. If the angle movement is small, continue to S3.     -   S3. Check if the filtered tangential acceleration data (filtered         using a short filter) is stable and close to a bias trained by         using the same short filter when the door is closed and at a         stationary position. If the answer is yes, a door close event is         reported; otherwise continue to S4.     -   S4. Check if the filtered tangential acceleration data (filtered         using a long filter) is stable and close to a bias trained by         using the same long filter when the door is closed and at a         stationary position. If the answer is yes, a door close event is         reported.

The short filter ensures that successful detection can be promptly completed in normal conditions and thus condition C1 is met. The long filter ensures that robust and reliable detection is possible in adverse conditions (e.g., in strong winds or on an open sea or in other unstable environments) and thus condition C2 is met.

FIGS. 9A-9B illustrate a procedure where a long filter and a short filter are used. In FIGS. 9A-9B, similar tasks as those depicted in FIGS. 8A-8B are assigned the same reference numerals. The following describes just the changed tasks or new tasks in FIGS. 9A-9B, as compared to the tasks of FIGS. 8A-8B.

Task 906: Based on the acceleration data (t_(i), r_(i), v_(i)) from the accelerometer received at 804, first filtered acceleration data (t′_(i), r′_(i), v′_(i)) and first variances (σ_(t,i) ², σ_(r,i) ², σ_(v,i) ²) are derived using the short IIR filter, and second filtered data (t″_(i)t″_(i−1) . . . t″_({circumflex over (ι)})) and second variances (Δ_(t,i) ², Δ_(r,i) ², Δ_(v,i) ²) are derived using the long IIR filter.

Task 924: If it is determined at task 822 that there is a possible door event, then the procedure activates the gyroscope, and the procedure sets i*=and determines a threshold T_(G). T_(G) may be adjusted according to σ_(t,i) ² . . . σ_(t,i−K) ², e.g., if significantly large values are observed in σ_(t,i) ² . . . σ_(t,i−K) ²,T_(G) may be adjusted higher. Let U denote a positive threshold, and let N(U) denote the number of times that

σ_(t,i) ² . . . σ_(t,i−K) ² are over U, i.e., N(U)=|{j: σ_(t,j) ²>U, i−K≤j≤i}|, where |S| denotes the cardinality of a set S. Then if N(U) is less than a specified threshold, then T_(G) is set to a default value, say 3 seconds; otherwise, if N(U) is greater than or equal to the specified threshold, then T_(G) is adjusted to a larger value, say 5 seconds. The threshold U may be learned from offline training data, and may depend upon what filter is being used. Example values of U are 0.1 meter per squared second (m/s²), 0.5 m/s², 1 m/s², or another value. The threshold used to check N(U) is likely dependent upon the sampling frequency f_(s), and U. Example values of such a threshold for f_(s)=50 Hz is 25, 30, 50, 100, or another value.

Task 830: If the elapsed time (i−{circumflex over (ι)}) is greater than or equal to T_(A), then the procedure determines based on the filtered tangential acceleration data t′_(i)t′_(i−1) . . . t′_({circumflex over (ι)})(filtered using the short filter) if the door is in the closed position. If not (which means that the procedure is unable to determine the door closed status using filtered tangential acceleration data filtered using the short filter), then the procedure proceeds to task 934.

Task 832: If it is determined at task 830 that the door is in the closed position, then the procedure changes the door status to “Closed,” and can send an indication of the closed status to a target entity.

Task 934: If the procedure is unable to determine (at 830) based on the filtered acceleration data t′_(i)t′_(i−1) . . . t′_({circumflex over (ι)})(filtered using the short filter) that the door is not in the closed position, then the procedure determines another threshold, T_(B)>T_(A), based on t′_(i)t′_(i−1) . . . t′_({circumflex over (ι)}) and σ_(t,i) ², σ_(t,i−1) ² . . . σ_(t,{circumflex over (ι)}) ². T_(B) may be based on t′_(i)t′_(i−1) . . . t′_({circumflex over (ι)}) and σ_(t,i) ², σ_(t,i−1) ² . . . σ_(t,{circumflex over (ι)}) ² by using a method similar to the one used to determine T_(G) above. That is, T_(B) may be adjusted higher if significantly large values are observed in σ_(t,i) ²σ_(t,i−1) ² . . . σ_(t,{circumflex over (ι)}) ². Similar to the technique discussed above for determining T_(G), the procedure can choose between a default value and a second value that is larger than the default value for T_(B). In addition, the filtered tangential acceleration data t′_(i)t′_(i−1) . . . t′_({circumflex over (ι)})(filtered using the short filter) may be used to adjust T_(B). Specifically, the procedure can check the number of times N_(t) that t′_(i)t′_(t−1) ² . . . t′_({circumflex over (ι)}) deviate from a trained mean, i.e., how many times the following condition is not met in the time period threshold, then T_(B) is determined according to σ_(t,i) ²σ_(t,i−1) ² . . . σ_(t,{circumflex over (ι)}) ² by using a method similar to that described for T_(G) above; otherwise, T_(B) is adjusted to a third value that is larger than the default value. Note that the second value and the third value may be the same in some cases.

Task 936: The procedure determines if the elapsed time (i−{circumflex over (ι)}) is greater than or equal to T_(B). If not, then the procedure returns to task 802.

Task 938: If the elapsed time (i−{circumflex over (ι)}) is greater than or equal to T_(B), then the procedure determines based on the filtered tangential acceleration data t″_(i)t″_(t−1) . . . t″_({circumflex over (ι)})(filtered using the long filter) if the door is in a closed position. If the procedure is able to determine that the door is in the closed position, then the procedure proceeds to task 832. However, if the procedure is unable to determine that the door is in the closed position, then the procedure returns to task 802.

Note that the biases used to determine whether the door is closed or not based on t″_(i)t″_(t−1) . . . t″_({circumflex over (ι)}) can be different from the biases used together with t′_(i)t′_(t−1) . . . t′_({circumflex over (ι)})These biases may be trained using a method similar to that described below, but with its own set of parameters, which in turn depend upon the filter (short filter or long filter) selected.

Motion Detection

Door status detection is enabled only when the moveable platform is not in motion. As discussed above, to detect the motion status of the moveable platform, the motion detection module 208 (FIG. 2A) makes use of acceleration data from an accelerometer (e.g., 112 in FIG. 2A). Specifically, let v_(i) denote the vertical (gravitational) component of the acceleration data (hereinafter referred to as the “vertical acceleration data”) from the accelerometer at time instant i. The proposed solution detects the motion status as follows.

FIG. 10 is a flow diagram of a motion detection procedure according to some examples, which can be performed by the motion detection module 208, for example. The following describes tasks of FIG. 10.

Task 1002: The motion detection procedure filters the vertical acceleration data v_(i) to obtain filtered vertical acceleration data v _(i), and to estimate a local variance σ_(v,i) ².

Task 1004: If the variances (variance values) in a motion detection time window between time instants i and i−T(σ_(v,i) ² . . . σ_(v,i−T) ²) remain above a specified threshold L>0 (i.e., each of σ_(v,i) ² . . . σ_(v,i−T) ²) remains above L), the motion detection procedure proceeds to task 1005; otherwise, the motion detection procedure continues to task 1006. The motion detection procedure detects the variances in the motion detection time window between time instants i and i−T being above L by using a counter to count a number of time instants that the variances are above L; if the counter counts that there has been T consecutive variances above L, then the motion detection procedure proceeds to task 1005. T is a specified constant set according to the sampling frequency f_(s) of the accelerometer. An example value of T is 5f_(s) or 10f_(s) or some other value.

Task 1005: The motion detection procedure sets the motion status to “in motion” and continues to task 1010.

Task 1006: The motion detection procedure detects whether there is a falling edge in the variances between time instants i and i m (σ_(v,i) ² . . . σ_(v,i−m) ²) where m is a specified positive integer number. If a “falling edge” (explained below) is detected, the procedure proceeds to task 1007; otherwise, the motion detection procedure continues to task 1008.

Task 1007: The motion detection procedure sets the motion status to “no motion”, and continues to task 1010.

Task 1008: If the variances in a motion detection time window between time instants i and i−T (σ_(v,i) ² . . . σ_(v,i−T) ²) remain below a specified threshold 0<U<L, the motion detection procedure proceeds to task 1009; otherwise the motion detection procedure proceeds to task 1010. The motion detection procedure detects the variances in the motion detection time window between time instants i and i−T being below U by using a counter to count a number of time instants that the variances are below U; if the counter counts that there has been T consecutive variances above U, then the motion detection procedure proceeds to task 1009.

Task 1009: The motion detection procedure continues to set the motion status to “no motion”.

Task 1010: The motion detection procedure increments i, i=i+1, and re-iterates tasks 1002-1009.

FIG. 11 shows a curve 1102 that represents variances (vertical axis) as a function of time (horizontal axis). FIG. 11 also depicts the thresholds L and U, as well as a falling edge 1104 in the variances. In FIG. 10, the falling edge 1104 is detected in task 1106, based on a detection of variances in a falling edge time window between time instants i and i−m (σ_(v,i) ² . . . σ_(v,i−m) ²) A “falling edge” refers to a drop in the variances from a level that is above the threshold L to a level that is below the threshold U. The falling edge 1104 indicates a transition of the moveable platform from being in motion to being not in motion.

In FIG. 11, prior to the falling edge 1104, the moveable platform is indicated to be in motion since the variances in a motion detection time window between time instants i and i−T (σ_(v,i) ² . . . σ_(v,i−T) ²) before the falling edge 1104 is above the threshold L. After the falling edge 1104, the moveable platform is indicated to be not in motion if the variances in a motion detection time window between time instants i and i−T (σ_(v,i) ² . . . σ_(v,i−T) ²) remain below U.

When f_(s)=50 Hz, an example value of L is 0.5 and an example value of U is 0.08. When the sampling frequency f_(s) changes, different L and U can be used. In other examples, other values of L and U can be used.

Note that the proposed motion detection solution above is asymmetric in that it uses both edge detection and a counter associated with an upper bound U to detect “no motion” and it uses only a counter associated with a lower bound to detect “in motion”. The primary reason for such an asymmetric design is that the requirements for detecting “in motion” and those for detecting “no motion” are different.

A “no motion” status is detected within a few seconds (depending upon the sampling frequency of the accelerometer) after the moveable platform comes to a stop so that door status detection is ready to use. Since detection of a falling edge can be faster than determining whether σ_(v,i) ² . . . σ_(v,i−T) ² remains below U, the solution chooses to use a hybrid approach of detecting “no motion” status where both edge detection and a variance upper bound are used.

The detection of “in motion” status is expected to be robust but is subject to less stringent time constraint than the detection of “no motion” status.

In task 1002 in FIG. 10, an IIR filter with coefficient α may be used to filter the vertical acceleration data v_(i) and to estimate σ_(v,i) ² recursively as follows.

v _(i) =αv _(i)+(1−α) v _(i−1),

V _(v,i) =αv _(i) ²+(1−α) V _(v,i−1),

σ_(v,i) ² =V _(v,i)−( v _(i))².

In the foregoing, the variance σ_(v,i) ² of the vertical acceleration data at time point i is computed based on calculating a square of the vertical acceleration data (v_(i) ²). Examples of the coefficient α are 0.008 and 0.016 when the sampling frequency of the accelerometer is 50 Hz. The coefficient α may be scaled by f_(s)/50 when the sampling frequency f_(s) is not 50 Hz. In other examples, other values of the coefficient α may be used.

In some cases, the variance σ_(v,i) ² may be further filtered by using a second IIR filter to obtain σ _(v,i) ² for more stability. In these cases, σ _(v,i) ² will be used in place of σ_(v,i) ² in the motion detection solution above. An example of such a second IIR filter is a filter with coefficient α set to 0.02 or some other value.

Training

To use the first filtered tangential acceleration data t′_(i)t′_(i−1) . . . t′_({circumflex over (ι)})(filtered using the short filter) to detect whether a door is in a closed position, the DOC process according to some implementations checks if both of the following conditions hold for all t′_(i)t′_(i−1) . . . t′_(i−D), where D is a specified constant depending upon the sampling frequency f_(s). An example value of D is 2f_(s) which is equivalent to 2 seconds in an example. In other examples, other values of D can be used.

|t′ _(i)−μ _(t) |<C ₁ μ _(r) +C ₂√{square root over (σ _(t) ²)}

σ_(t,i) ² <C3σ_(t) ²

In the above, μ _(t), μ _(r), and σ _(t) ² are respectively the tangential bias due to gravity, the radial bias due to gravity, and the tangential noise level. Similar checks are performed for the second filtered tangential acceleration data t″_(i)t″_(i−1) . . . t″_({circumflex over (ι)})(filtered using the long filter), where a different set of (μ _(t), μ _(r), σ _(t) ²) may be used. In the above, an example value of the constant C₁ is 0.0175, which is roughly equal to sin(1*pi/180) and obtained by using the Taylor series of the sine or cosine function. An example value of the constant C₂ is 2.5758 and an example value of the constant C₃ is (C₂)². In other examples, other values of C₁, C₂ and C₃ can be used.

In accordance with some implementations, the DOC process can train the bias values and the noise levels (μ _(t), μ _(r), σ _(t) ²). The training process is initiated as soon as the moveable platform's motion status is detected to be in “no motion”. Let i₀ denote the starting time of the training (or learning) process.

To account for the possibility that a previous known door state may be wrong, the training process can run as long as one of the following conditions is true:

-   -   a. The current door status is either closed or unknown.     -   b. σ_(t,i) ²<F and optionally σ_(r,i) ²<F, where F is a         specified threshold. An example value of F is 0.01 when the         sampling frequency is 50 Hz. In other examples, other values of         F can be used.

The training process computes the mean and variance of the radial acceleration data (μ_(r,i), σ_(r,i) ²) and the mean and variance of the tangential acceleration data (μ_(t,i), σ_(t,i) ²). For example, (μ_(t,i), σ_(t,i) ²) may be computed using Eqs. 1-4 discussed above, which are reproduced below.

$\begin{matrix} {{\mu_{t,i} = \frac{S_{t,i}}{K}},} & \left( {{Eq}.\mspace{14mu} 1} \right) \\ {{\sigma_{t,i}^{2} = {\frac{S_{t^{2},i}}{K} - \mu_{t,i}^{2}}},} & \left( {{Eq}.\mspace{14mu} 2} \right) \\ {{S_{t,i} = {\sum\limits_{j = {i - K + 1}}^{i}t_{j}}},} & \left( {{Eq}.\mspace{14mu} 3} \right) \\ {S_{t^{2},i} = {\sum\limits_{j = {i - K + 1}}^{i}{t_{j}^{2}.}}} & \left( {{Eq}.\mspace{14mu} 4} \right) \end{matrix}$

The values of (μ_(r,i), σ_(r,i) ²) can be computed in a similar manner. In the above, K is the window length used to compute the mean and variances, and may depend upon the sampling frequency f_(s).

The training process of learning stationary values of acceleration data (radial acceleration data and tangential acceleration data) is depicted in FIG. 12.

Task 1202: The process initializes the following buffers that are used in the training process: A_(M), A_(t), A_(r), B_(t), and B_(r). The A_(t) buffer is used to store a computed stationary mean value of the tangential acceleration data, the buffer A_(r) is used to store a computed stationary mean value of the radial acceleration data, the buffer B_(t) is used to store a computed stationary variance value of the tangential acceleration data, and the buffer B_(r) is used to store a computed stationary variance value of the radial acceleration data. The buffer A_(M) is used to store a stationary variance value of the acceleration magnitude (M_(i) calculated according to M_(i)=√{square root over (r_(i) ²+t_(i) ²+v_(i) ²)}) of the acceleration data.

Let N be a positive integer. Example values of N can be 7, 8, 11, 13, 16, 17, and so forth. The training process then divides the sequence of acceleration data samples into N sub-sequences. In some examples, N buffers are used to store the respective variance and mean values computed for the respective sub-sequences.

If N buffers are used, then there are: N A_(M) buffers, represented as A_(M,0) to A_(M,N−1); N A_(t) buffers, represented as A_(t,0) to A_(t,N−1); N A_(r) buffers, represented as A_(r,0) to A_(r,N−1); N B_(t) buffers, represented as B_(t,0) to B_(t,N−1); and N B_(r) buffers, represented as B_(r,0) to B_(r,N−1).

Although FIG. 12 refers to an example where specific buffers are used, it is noted that in other examples, other data structures can be used to store the respective values.

Task 1204: The training process computes the mean and variance of the radial acceleration data (μ_(r,i), σ_(r,i) ²), and the mean and variance of the tangential acceleration data (μ_(t,i), σ_(t,i) ²) using computations similar to that performed in Eqs. 1-4 above.

Task 1206: Since a sequence of acceleration data samples is divided into N sub-sequences, in some examples, N buffers are used to store the respective variance and mean values computed for the respective sub-sequences. The training process updates the buffers according to local minima values, as follows. Let s=i mod N. If max(σ_(t,i) ², σ_(r,i) ²)<A_(M,s), then update the buffers as follows.

A _(M,s)=max(σ_(t,i) ²,σ_(r,i) ²),

A _(t,s)=μ_(t,i),

A _(r,s)=μ_(r,i),

B _(t,s)=σ_(t,i) ²,

B _(r,s)=σ_(r,i) ².

In the foregoing, s=0 . . . N−1, and if max(σ_(t,i) ², σ_(r,i) ²) at time point i is less than the value in the buffer A_(M,s), then the buffer A_(M,s) is updated with the value max(σ_(t,i) ², σ_(r,i) ²) (i.e., maximum of σ_(t,i) ² and σ_(r,i) ²), and the remaining buffers A_(t,s), A_(r,s), B_(t,s), and B_(r,s) are updated with respective mean and variance values μ_(t,i), μ_(r,i), σ_(t,i) ², and σ_(r,i) ².

Effectively, after all of the tangential and radial acceleration data samples have been processed, the N buffers A_(t,0) to A_(t,N−1) contain N respective local minima of the mean μ_(t,i) of the tangential acceleration data samples. Similarly, the N buffers A_(r,0) to A_(r,N−1) contain N respective local minima of the mean μ_(r,i) of the radial acceleration data samples, the N buffers B_(t,0) to B_(t,N−1) contain N respective local minima of the variance σ_(t,i) ², of the tangential acceleration data samples, and the L buffers B_(r,0) to B_(r,N−1) contain N respective local minima of the variance σ_(r,i) ² of the radial acceleration data samples.

Task 1208: If i−i₀≥T₀ or a door open event is detected, where T₀ is a specified time limit for training since motion status is changed to “no motion,” then the training process updates the stationary mean and variance values of the radial and tangential acceleration data according to global extrema. More specifically, in some examples, the training process finds the index l*=arg max_(l) A_(M,l), which finds the maximum (an example of the global extrema) of each of the variance values in the N buffers A_(M,0) to A_(M,N−1). Note that T₀ represents a learning time period expressed as a number of acceleration data samples. An example value of T₀ is 30*50, which is equivalent to 30 seconds when the sampling frequency is 50 Hz. In other examples, other values of T₀ can be used. After learning for T₀ samples, the mean and variance values of the radial and tangential acceleration data is updated as μ _(t), μ _(r), σ _(t) ², and σ _(r) ². Task 1208 includes:

-   -   recording μ _(t)=A_(t,l*) and μ _(r)=A_(r,l*) as the stationary         estimates of tangential and radial components, respectively;     -   recording σ _(t) ²=B_(t,l*) and σ _(r) ²=B_(r,l*) as the         estimates of tangential and radial variance corresponding to the         stationary values, respectively; and     -   resetting A_(M) such that A_(M,l)=M*, l=0, . . . , N−1.

After the initial training period since motion status changes (the initial training process might end either after T₀ samples are processed or at a door open event), a longer training period T₁ may be used. For example, T₁ may be set to 8*3600*50, which is equivalent to 8 hours when the sampling frequency is 50 Hz. Note that the initial training period applies whenever the motion status is switched from “in motion” to “no motion”.

In the above, the task 1206 essentially computes

min{σ_(M,i) ² ;i mod N=s}.  (Eq. 12)

As such, the training process described above is a maxmin method. In other examples, a minmax method can be used to estimate the stationary radial and acceleration mean and variance values by altering the order of minimization and maximization operations above.

In some cases, the above training process can be simplified by using σ_(t,i) ² in place of max(σ_(t,i) ²,σ_(r,i) ²).

In some examples, μ_(t,i) and σ_(t,i) ² may be approximated by using an IIR filter with coefficient α as follows.

μ_(t,i) =αt _(i)+(1−α)μ_(t,i−1),

V _(t,i) =αt _(i) ²+(1−α) V _(t,i−1),

σ_(v,i) ² =V _(v,i)−(μ_(t,i))².

Similarly, μ_(r,i) and σ_(r,i) ² may be approximated by using the IIR filter.

More generally, finding the mean and variance of the tangential and radial acceleration data values μ _(t), μ _(r), σ _(t) ², and σ _(r) ² involves 1) finding local extrema values (minimum values or maximum values depending upon whether the maxmin method or the minmax method is used) for respective sub-sequences {σ_(M,i) ²; i mod L=s}, 2) then finding a global extrema (either maximum or minimum depending upon whether the maxmin method or the minmax method is used) in the local extrema values, and 3) finally determining the mean and variance of the tangential and radial acceleration data values that correspond to the global extrema found (e.g., co-located). For example, if the global extrema is reached at time instant i*, then the mean and variance computed at time instant i*, i.e., μ_(t,i*), μ_(t,i*), σ_(t,i*) ², and σ_(r,i*) ² may be used as the estimates of μ _(t), μ _(r), σ _(t) ², and σ _(r) ², respectively.

The stationary mean and variance values of the tangential and radial acceleration data values μ _(t), μ _(r), σ _(t) ², and σ _(r) ² can be used directly in detecting convergence of the tangential and radial acceleration data as discussed above for determining whether a door close event has occurred. For each learning period, the current stationary mean tangential and acceleration data values μ _(t) and μ _(r) can be used for the next T samples until new estimates are available for the next learning period.

Combined Door Status Detection and Motion Detection

In some cases, activation of the gyroscope in the DOC process may be further improved to distinguish normal door operations from full-body moveable platform movement, e.g., the moveable platform may turn when a vehicle towing the moveable platform is making a turn or the moveable platform may swivel around when the moveable platform is lifted by a crane. In these cases, vertical acceleration data may be used in conjunction with tangential acceleration data in the DOC process. This is based on the observation that vertical variance is typically higher in full body movement than in normal door operations. As such gi_(i) (the gyroscope activation indication) may be set to 0 (to maintain the gyroscope deactivated) if large vertical variance is observed in the absence of large tangential variance. Note that when the moveable platform is moving with its door in the open position, significant tangential variance may be observed. In one example, gi_(i) is set to 0 if the following conditions are both satisfied:

-   -   i) σ_(v,i) ² is greater than a specified threshold, say 0.2,         0.3, 1, or some other value.     -   ii) σ_(t,i) ² is less than a specified threshold, say 5, 10, 20,         or some other value.

In another example, a third condition σ_(v,i) ²>σ_(t,i) ² may have to be satisfied as well. Generally, the foregoing criteria specify that the gyroscope is not to be turned on if the vertical variance is large (greater than a specified threshold), and the tangential variance is small (less than a specified threshold).

To further improve robustness of door status detection against full body movement, in some cases the DOC process may be modified to track vertical acceleration data in determining whether the door is in the open position or not. Specifically, as shown in FIG. 13, the DOC process starts in an idle state, where the gyroscope is deactivated. In response to detecting a trigger (such as based on the condition in task 822 of FIG. 9A), the DOC process transitions to a gyroscope waiting state 1304 (where gyroscope calibration can be performed as part of activating the gyroscope). Upon completion of the gyroscope calibration, the gyroscope is ready for operation, and the DOC process transitions to the gyroscope active state 1306 where the gyroscope waits for time duration T_(G) and determines whether the door has moved to the open position in response to the aggregate value, a_(j), computed based on measurements from the gyroscope over the time duration T_(G). If the door is detected to be open, the DOC process transitions back to the idle state 1302.

However, if the time duration T_(G) expires and the DOC process detects a door open angle (the angle of rotation of the door is greater than θ_(open) as determined at task 816 in FIG. 9A) but that the moveable platform is not stationary, the DOC process transitions from the state 1306 to a state 1308 where the DOC process may continue tracking the vertical variance, σ_(v,i) ², of the vertical acceleration data for a time duration T_(O) to make sure that the angle movement is not due to full body movement of the moveable platform due to making a turn or some other movement. For example, the DOC process may report that the door is in the open position only if σ_(v,i) ² remains below a specified threshold, e.g., 0.05, 0.1, 0.2, or some other value, which may depend upon the moveable platform and/or door type, for 0.5, 1, 2 seconds, or some other time interval. In the above, T_(O) may be set for 3, 5, 10 seconds, or some other time duration.

The DOC process returns from the state 1308 to the idle state 1302 in response to the door open status being successfully detected or in response to the time duration T_(O) expiring and the DOC unable to conclusively determine that the door is open.

From the state 1306, if the time duration T_(G) expires and the DOC process detects a small angle of rotation of the door (the angle of rotation of the door is less than θ_(open)), the DOC process transitions from the state 1306 to a state 1310 where the DOC process uses short filtered tangential acceleration data (filtered using the short filter) to determine after passage of the time duration T_(A) (see tasks 828 and 830 in FIG. 9B) whether the door is in the closed state. If a door close status is detected, the DOC process returns from the state 1310 to the idle state 1302.

If the time duration T_(A) expires and the detection using the short filtered tangential acceleration data is inconclusive, the DOC process transitions from the state 1310 to the state 1312, where the DOC process uses short filtered tangential acceleration data (filtered using the short filter) to determine after passage of the time duration T_(B) (see tasks 936 and 938 in FIG. 9B) whether the door is in the closed state. If a door close status is detected or the time duration T_(B) expired and the door close detection is inconclusive, the DOC process returns from the state 1312 to the idle state 1302.

In some other cases, the DOC process may make use of the result of motion detection. For example, if a moveable platform is detected to be in motion, tangential acceleration data is likely subject to significant variation if the door is open. Such observation can lead to the following modifications to the DOC process. If all of the following conditions are satisfied, the DOC process determines that the door is in the closed position.

a) Motion is detected, e.g., by observing vertical acceleration data as described above.

b) Door status is unknown or in the open position.

c) Tangential variance σ_(t,i) ² remains below a specified threshold, e.g. 10, 20, or some other value, for an extended period of time, e.g. 20, 30, 60 seconds, or some other time duration.

System Architecture

The processes (e.g., motion detection process, DOC process, or training process) described above can be performed by the processor(s) 118 of the sensor device 108, or by processor(s) of a computer system (implemented with a computer or multiple computers), where the computer system is separate from the sensor device 108. In some examples, the processes can be performed by machine-readable instructions executable on the processor(s) 118. The machine-readable instructions can be stored in a non-transitory computer-readable or machine-readable storage medium. The storage medium can include any or some combination of the following: a semiconductor memory device such as a dynamic or static random access memory (a DRAM or SRAM), an erasable and programmable read-only memory (EPROM), an electrically erasable and programmable read-only memory (EEPROM) and flash memory; a magnetic disk such as a fixed, floppy and removable disk; another magnetic medium including tape; an optical medium such as a compact disk (CD) or a digital video disk (DVD); or another type of storage device. Note that the instructions discussed above can be provided on one computer-readable or machine-readable storage medium, or alternatively, can be provided on multiple computer-readable or machine-readable storage media distributed in a large system having possibly plural nodes. Such computer-readable or machine-readable storage medium or media is (are) considered to be part of an article (or article of manufacture). An article or article of manufacture can refer to any manufactured single component or multiple components. The storage medium or media can be located either in the machine running the machine-readable instructions, or located at a remote site from which machine-readable instructions can be downloaded over a network for execution.

In the foregoing description, numerous details are set forth to provide an understanding of the subject disclosed herein. However, implementations may be practiced without some of these details. Other implementations may include modifications and variations from the details discussed above. It is intended that the appended claims cover such modifications and variations. 

What is claimed is:
 1. An apparatus comprising: a sensor device comprising an accelerometer, the sensor device for mounting on a moveable platform; and at least one processor configured to: compute a variance based on acceleration data from the accelerometer; and determine, using the computed variance, whether the moveable platform is in motion.
 2. The apparatus of claim 1, wherein the variance based on the acceleration data comprises variance values based on the acceleration data, and wherein the at least one processor is to determine whether the moveable platform is in motion by: responsive to determining that the variance values are above a first threshold, indicating that the moveable platform is in motion.
 3. The apparatus of claim 2, wherein the at least one processor is configured to determine whether the moveable platform is in motion by: determining whether at least a portion of the variance values have fallen from a point at or above the first threshold to a point at or below a second threshold, and responsive to determining that the at least a portion of the variance values have fallen from the point at or above the first threshold to the point at or below the second threshold, indicating that the moveable platform is not in motion.
 4. The apparatus of claim 3, wherein the first threshold is greater than the second threshold.
 5. The apparatus of claim 3, wherein the indicating that the moveable platform is in motion is responsive to the variance values within a specified time window being above the first threshold.
 6. The apparatus of claim 3, wherein the at least a portion of the variance values is within a specified time window.
 7. The apparatus of claim 3, wherein the at least one processor is configured to determine whether the moveable platform is in motion by: after indicating that the moveable platform is not in motion, determining whether the variance values remain below a second threshold, and responsive to determining that the variance values remain below the second threshold, continuing to indicate that the moveable platform is not in motion.
 8. The apparatus of claim 1, wherein the at least one processor is configured to further: filter, using a filter, the acceleration data to produce filtered acceleration data, wherein the variance is based on the filtered acceleration data.
 9. The apparatus of claim 8, wherein the filter is an infinite impulse response (IIR) filter.
 10. The apparatus of claim 9, wherein the at least one processor is configured to further: filter a square of the acceleration data using the IIR filter; and compute the variance using the filtered square of the acceleration data.
 11. The apparatus of claim 9, wherein the at least one processor is configured to further: filter variance using another IIR filter to produced a filtered variance; and determine whether the moveable platform is in motion using the filtered variance.
 12. The apparatus of claim 1, wherein the at least one processor is configured to further: responsive to determining that the moveable platform is in motion, disable a process for determining an open/close status of a pivotable barrier on the moveable platform, the pivotable barrier being moveable between an open position and a closed position; and responsive to determining that the moveable platform is not in motion, enable the process for determining an open/close status of a pivotable barrier.
 13. A method comprising: computing, by at least one processor, variance values based on acceleration data from an accelerometer on a moveable platform; and determining, by the at least one processor using the computed variance values, whether the moveable platform is in motion.
 14. The method of claim 13, wherein determining that the moveable platform is in motion is asymmetric to determining that the moveable platform is not in motion.
 15. The method of claim 13, wherein the determining comprises: responsive to determining that a consecutive number of the variance values are above a first threshold, indicating that the moveable platform is in motion.
 16. The method of claim 15, wherein the determining further comprises: determining whether at least a portion of the variance values have fallen from a point at or above the first threshold to a point at or below a second threshold, and responsive to determining that the at least a portion of the variance values have fallen from the point at or above the first threshold to the point at or below the second threshold, indicating that the moveable platform is not in motion.
 17. The method of claim 15, wherein indicating that the moveable platform is in motion is responsive to the variance values within a first specified time window being above the first threshold.
 18. The method of claim 17, wherein the at least a portion of the variance values is within a second specified time window.
 19. The method of claim 15, wherein the determining further comprises: after indicating that the moveable platform is not in motion, determining whether a consecutive number of the variance values remain below a second threshold, and responsive to determining that the consecutive number of the variance values remain below the second threshold, continuing to indicate that the moveable platform is not in motion.
 20. A non-transitory storage medium storing instructions that upon execution cause at least one processor to: compute variance values within a specified time window based on acceleration data from an accelerometer on a moveable platform; and determine, based on comparing the computed variance values within the specified time window to upper and lower thresholds, whether the moveable platform is in motion. 